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CLIC workshop 2015 EXTRACTION KICKER STRIPLINE MEASUREMENTS C. Belver-Aguilar (IFIC) On behalf of: A. Faus-Golfe (IFIC), F. Toral (CIEMAT), M.J. Barnes (CERN), H. Day (CERN)
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1) INTRODUCTION 29 th Jan 2015 CLIC’15 workshop 1/15 Laboratory tests: S-parameters Longitudinal beam coupling impedance Transverse beam coupling impedance HV Tests The design of the striplines and their components has been published in the PRSTAB 17, 071003 (July 2014).
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2) S 11 PARAMETER MEASUREMENT 29 th Jan 2015 CLIC’15 workshop 2/15 Three sources of impedance mismatch: The characteristic impedance of the connection between the electrode and the feedthrough is not constant. In the odd mode, the characteristic impedance is lower than 50 Ω. The presence of electrode supports increase the reflections
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HYBRID SPLITTER DICONEX TERMINATING RESISTOR To the Network Analyzer (NA) Agilent E5071C 2-port LOW-LOSS HTC-50-7-2 CABLES 2) S 11 PARAMETER MEASUREMENT 29 th Jan 2015 CLIC’15 workshop 3/15
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Diconex 50 Ω resistors are presently being used for HV testing of the inductive adder. The Diconex terminating resistors are not ideal, their value is frequency dependent. Frequency content of the driving pulse ≈ 0.01 GHz resistor impedance variation of ± 0.2%. The impedance of the Diconex resistor is expected to be acceptable for the inductive adder. 29 th Jan 2015 CLIC’15 workshop 4/15
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S 11 PARAMETER MEASURED AND SIMULATED ODD MODE EVEN MODE HQ 50 Ω resistors were used from the calibration kit of the NA, with a ‘constant’ characteristic impedance. 29 th Jan 2015 CLIC’15 workshop 5/15
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COMPARISON BETWEEN HQ RESISTORS AND DICONEX TERMINATING RESISTORS EVEN MODE There are more resonances when the striplines are terminated with the Diconex resistors, at frequencies above ≈ 0.2 GHz. They are expected to influence the beam coupling impedance. 29 th Jan 2015 CLIC’15 workshop 6/15
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2) LONGITUDINAL BEAM COUPLING IMPEDANCE MEASUREMENT To measure the longitudinal beam coupling impedance, a single wire is inserted into the striplines aperture and the signal transmission (S 21 ) is measured, from which the longitudinal impedance can be calculated. The diameter of the wire used for the measurement should be as small as possible to obtain a high line impedance, which best reflects the fact that the beam acts as an ideal current source. For our measurements a 0.5 mm diameter wire made up of ‘soft copper’ has been used. 29 th Jan 2015 CLIC’15 workshop 7/15
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The NA and the connecting coaxial cables have 50 Ω characteristic impedance, while the TEM line is composed of the wire and the striplines: these have impedance Z line. For a wire between two parallel plates: Z line (Ω) = 60 ln (1.27D/d) = 235.7 Ω SINGLE WIRE TRANSMISSION METHOD 29 th Jan 2015 CLIC’15 workshop 8/15
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Matching of the characteristic impedance of the line Z line to the system impedance Z 0 by means of a single series carbon resistor at both ends of the wire (R = 235.7 Ω – 50 Ω ≈ 185 Ω). For the calculation of the longitudinal impedance, from the measured S 21 parameter, the log formula has been used: Z || = -2Z line ln(S 21 ) Matching of the line 29 th Jan 2015 CLIC’15 workshop 9/15
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The resistively matched measurements generally gives good results below a few hundred MHz but the residual mismatch in the system can cause large oscillations which mask the true impedance. 29 th Jan 2015 CLIC’15 workshop 10/15
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The longitudinal beam coupling impedance measurements have been repeated, using the resonant method. The TEM line adapted by replacing the connection of the wire to the inner conductor of the measurement lines by capacitive coupling. 29 th Jan 2015 CLIC’15 workshop 11/15 RESONANT METHOD
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3) HV TESTS DC HV power supply, with a maximum voltage of 12.5 kV: each stripline is powered with an equal but opposite polarity DC voltage. Vacuum level of ≈10 -7 mbar. Method: a HV prove is connected to an oscilloscope in order to see the voltage drop due to a spark. 29 th Jan 2015 CLIC’15 workshop 12/15
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DETECTION OF ELECTRICAL BREAKDOWN The oscilloscope is set up to trigger on either: Negative voltage (e.g. -8.5 kV) which increases through a threshold of -6 kV (CH1); OR Positive voltage (e.g. +8.5 kV) which decreases through a threshold of +6 kV (CH2); The number of triggers (acquisitions) is the total number of breakdowns. 29 th Jan 2015 CLIC’15 workshop 13/15
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PROCEDURE Both electrodes have equal but opposite polarity DC voltage applied. Increase voltages in small (few hundred volts) steps and wait for several hours and count number of electrical breakdowns. Occasionally reduce voltage, or repeat test at same voltage, to determine whether conditioning has occurred (i.e. breakdown rate has reduced). 29 th Jan 2015 CLIC’15 workshop 14/15
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4) CONCLUSIONS The laboratory tests of the CLIC DR extraction kicker have been done, without beam, in order to characterize the electromagnetic response of the striplines. The measurements carried out with the NA have been the S 11 parameter and the longitudinal and transverse beam coupling impedance. In that case, a good agreement has been found between the laboratory tests and the CST simulations up to 0.25 GHz. Results for the resonant method and transverse beam impedance are being analyzed. DC HV tests have been carried out and analyzed. A maximum BDR/hour 0f 2.5 has been found with a voltage of 9.25 kV, which could be dangerous in the regions where the Macor rings are placed. 29 th Jan 2015 CLIC’15 workshop 15/15
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